Study on the bacterial midgut microbiota associated to different Brazilian populations of Lutzomyia longipalpis (Lutz &amp; Neiva) (Diptera: Psychodidae)

Gouveia, Cheryl; Asensi, Marise D.; Zahner, Viviane; Rangel, Elizabeth F.; Oliveira, Sandra M.P. de

doi:10.1590/S1519-566X2008000500016

Abstracts

The bacterial community associated with the midgut of three Brazilian Lutzomyia longipalpis (Lutz & Neiva) populations, two from endemic areas for visceral leishmaniasis (Jacobina, Bahia State and São Luís, Maranhão State) and one from a non-endemic area (Lapinha Cave, Minas Gerais State), was identified. Five groups, 35 females each, from each population were separated; a total of 175 females per collecting area were analyzed. The species identification was based on molecular and traditional bacteriological methods. All bacteria were either affiliated to non-Enterobacteriaceae, such as Acinetobacter, Burkholderia, Flavimonas, Pseudomonas and Stenotrophomonas, or and to Enterobacteriaceae, such as Citrobacter, Enterobacter, Escherichia, Klebsiella, Serratia, Pantoea, Morganella and Weeksella. Stenotrophomonas was found to be associated with all three populations studied. In addition, Serratia spp., which are well documented as laboratory contaminant of insects, were detected only in the Jacobina population. We also discuss the impact of the colonization of insect gut by bacteria on the development and transmission of pathogens.

Sand fly; visceral leishmaniasis; microorganism; gut microbiota

A flora bacteriana encontrada no intestino de populações brasileiras de Lutzomyia longipalpis (Lutz & Neiva) provenientes de duas áreas endêmicas para leishmaniose visceral (Jacobina, BA e São Luís, MA) e de uma área não endêmica (Gruta da Lapinha, MG) é descrita. Cinco grupos de 35 fêmeas de cada população foram separados, no total de 175 fêmeas analisadas por área de coleta. A identificação das espécies foi baseada em métodos moleculares e em métodos bacteriológicos tradicionais. As bactérias encontradas foram classificadas como pertencentes ao grupo das não-Enterobacteriaceae, como Acinetobacter, Burkholderia, Flavimonas, Pseudomonas, ou ao grupo das Enterobacteriaceae, como Stenotrophomonas, Citrobacter, Enterobacter, Escherichia, Klebsiella, Serratia, Pantoea, Morganella e Weeksella. Stenotrophomonas esteve presente nas três populações analisadas. Além disso, Serratia spp., grupo bem documentado como contaminante laboratorial de insetos, foi detectado apenas na população de Jacobina. O impacto da colonização do intestino de insetos por bactérias no desenvolvimento e transmissão de patógenos é discutido.

Flebotomíneo; leishmaniose visceral; microrganismo; microbiota intestinal

PUBLIC HEALTH

Study on the bacterial midgut microbiota associated to different Brazilian populations of Lutzomyia longipalpis (Lutz & Neiva) (Diptera: Psychodidae)

Estudo sobre as bactérias da microbiota intestinal de diferentes populações brasileiras de Lutzomyia Longipalpis (Lutz & Neiva) (Diptera: Psychodidae)

Cheryl Gouveia^I; Marise D. Asensi^II; Viviane Zahner^III; Elizabeth F. Rangel^IV; Sandra M.P. de Oliveira^V

^ILab. de Transmissores de Leishmanioses, FIOCRUZ, 21045-900, Rio de Janeiro, RJ, cheryl@ioc.fiocruz.br

^IILab. de Enterobacteriacea, FIOCRUZ, 21045-900, Rio de Janeiro, RJ, marise@ioc.fiocruz.br

^IIILab. de Sistemática Bioquímica, FIOCRUZ, 21045-900, Rio de Janeiro, RJ, vzahner@fiocruz.br

^IVLab. de Transmissores de Leishmanioses, FIOCRUZ, 21045-900, Rio de Janeiro, RJ, elizabethrangel@fiocruz.br

^VLab. de Transmissores de Leishmanioses, FIOCRUZ, 21045-900, Rio de Janeiro, RJ, soliver@ioc.fiocruz.br

ABSTRACT

The bacterial community associated with the midgut of three Brazilian Lutzomyia longipalpis (Lutz & Neiva) populations, two from endemic areas for visceral leishmaniasis (Jacobina, Bahia State and São Luís, Maranhão State) and one from a non-endemic area (Lapinha Cave, Minas Gerais State), was identified. Five groups, 35 females each, from each population were separated; a total of 175 females per collecting area were analyzed. The species identification was based on molecular and traditional bacteriological methods. All bacteria were either affiliated to non-Enterobacteriaceae, such as Acinetobacter, Burkholderia, Flavimonas, Pseudomonas and Stenotrophomonas, or and to Enterobacteriaceae, such as Citrobacter, Enterobacter, Escherichia, Klebsiella, Serratia, Pantoea, Morganella and Weeksella. Stenotrophomonas was found to be associated with all three populations studied. In addition, Serratia spp., which are well documented as laboratory contaminant of insects, were detected only in the Jacobina population. We also discuss the impact of the colonization of insect gut by bacteria on the development and transmission of pathogens.

Key words: Sand fly, visceral leishmaniasis, microorganism, gut microbiota

RESUMO

A flora bacteriana encontrada no intestino de populações brasileiras de Lutzomyia longipalpis (Lutz & Neiva) provenientes de duas áreas endêmicas para leishmaniose visceral (Jacobina, BA e São Luís, MA) e de uma área não endêmica (Gruta da Lapinha, MG) é descrita. Cinco grupos de 35 fêmeas de cada população foram separados, no total de 175 fêmeas analisadas por área de coleta. A identificação das espécies foi baseada em métodos moleculares e em métodos bacteriológicos tradicionais. As bactérias encontradas foram classificadas como pertencentes ao grupo das não-Enterobacteriaceae, como Acinetobacter, Burkholderia, Flavimonas, Pseudomonas, ou ao grupo das Enterobacteriaceae, como Stenotrophomonas, Citrobacter, Enterobacter, Escherichia, Klebsiella, Serratia, Pantoea, Morganella e Weeksella. Stenotrophomonas esteve presente nas três populações analisadas. Além disso, Serratia spp., grupo bem documentado como contaminante laboratorial de insetos, foi detectado apenas na população de Jacobina. O impacto da colonização do intestino de insetos por bactérias no desenvolvimento e transmissão de patógenos é discutido.

Palavras-chave: Flebotomíneo, leishmaniose visceral, microrganismo, microbiota intestinal

There are many species among Diptera, in which males and females feed on natural sugars, especially nectar, sap and aphid secretions. These sugars are the main source of carbohydrates for adults and complement the females diet, which also need blood feeding (Schlein 1986, Schlein & Warburg 1986, Samie et al. 1990). In this context, considering their food sources, these insects harbour microorganisms as a natural flora that can influence their life cycles (Brooks 1964, Alves 1986).

In nature, sand flies dipterous associate to the transmission of leishmaniasis feed on different kinds of sugars, so having the chance to acquire contaminating microorganisms, such as bacteria and fungi, that can eliminate the leishmaniotic infection or even kill the sand fly (Killick-Kendrick & Killick-Kendrick 1987, Schlein & Yuval 1987, Cameron et al. 1995).

Previous studies revealed that the introduction of transitory bacteria during the ingestion of sugars can exert a constant selective pressure on the development of Leishmania in the gut of its natural vector (Adler & Theodor 1927, Schlein et al. 1985, Pumpuni et al. 1996). It was suggested that the presence of a specific bacteria in the gut of an insect may affect the success a pathogen is transmitted by a vector (Pumpuni et al. 1996). Despite the apparent importance of the bacterial microbiota, there are few reports on the presence of bacteria in sand flies (Warburg 1991) and the midgut microbiota of Brazilian populations is unknown.

Some reports show a predominance of Gram negative rods in the midgut of wild-caught sand flies (Oliveira et al. 2000). For this reason we decided to investigate the bacterial microbiota present in the midgut of natural populations of L. longipalpis from different regions of Brazil (endemic and non endemic areas for visceral leishmaniasis). It is an important step to understand the microbial structure of populations of L. longipalpis, and allows identifying the organisms that might play a role in the insect life cycle and, possibly, in the pathogen transmission cycle.

Material and Methods

Field sampling. Sand flies were collected in a non-endemic area, Lapinha Cave (Minas Gerais State), and in two transmission areas of visceral leishmaniasis, Jacobina (State of Bahia) and São Luís (State of Maranhão), where L. longipalpis occurs in high density. The captures were performed from 2001 to 2004 using CDC light traps (Sudia & Chamberlain 1962), during a 12h interval from 6 p.m. to 6 a.m. In Jacobina and São Luís, traps were installed in the peridomicile in domestic animal shelters (hen houses and corrals), while inside the Lapinha Cave they were left about 50-80 cm from the ground level.

Specimen preparation. Sand flies were transported alive in a nylon cage to the laboratory, where selected females were transferred to plaster lined pots humidified with sterilized distilled water, in which insects remained in absolute abstinence of food until their processing. Five groups, 35 females each, from each population were separated; a total of 175 females per collecting area were analyzed. Females were killed at low temperature, surface-sterilized with sodium hypochlorite (5%), washed thrice with sterile distilled water and dissected in sterile PBS (phosphate buffered saline) under a hood for extracting the digestive tract and the Malpighian tubules.

Bacterial cultures and biochemical identification. The digestive tracts were put in a simple broth for enrichment. Afterwards the broth was spread on different culture media (DIFCO). The primary characterization of the microorganisms was based on the general aspects of colonies, Gram staining and selective biochemistry tests according to Holt et al. (1994). Bacteria were identified at species level according to the Crystal Enteric Fermenter/Nonfermenter (E/NF) Identification System (Becton Dickinson Inc., Cockeysville, Md.). This system contains modified conventional and unconventional biochemical and enzymatic tests and is designed to identify members of the family Enterobacteriaceae and common strains of clinical significance and glucose non-fermenting Gram negative bacilli. Details on the procedure for isolation and identification of bacteria can be found in Oliveira et al. (2000).

DNA extraction, purification and quantification. Template DNA for PCR screening was prepared by processing 1 ml of culture grown for 18h at 37°C or 30°C, using the GenomicPrep cell and tissue DNA kit (Amersham Pharmacia Biotech Inc.). DNA concentration of each bacterial strain was measured in a GeneQuant DNA Spectrophotometer (Amershan-Pharmacia).

PCR amplification of 16S rDNA partial sequences. Twenty-five nanograms of DNA were used for PCR reaction. Ultrapure water (Gibco) was used in all negative control reactions (without DNA) and in the preparation of PCR mixtures. Reaction mixtures for amplification of sequences encoding 16S rDNA contained 2 µl of template DNA (10 ng), 10 mM Tris-HCl (pH 8.3), 10 mM KCl, 0.1 mM of each deoxynucleoside triphosphate, 2.5 mM MgCl₂, 0.5 pmol of each primer, and 0.5 U of Taq DNA polymerase (Invitrogen). The broadly conserved Eubacterial 16S rDNA gene primers were p515f (gccagcagccgcggtaa; Escherichia coli position 515-533) and p806r (ggactaccagggtatctaat; E. coli position 806-787). The PCR amplification conditions consisted of 12 min at 95°C followed by 30 cycles of 95°C for 15s, 55°C for 20s and 72°C for 20s, and a single cycle of 72°C for 30 min on a 9600 Thermocycler (Perkin-Elmer/Applied Biosystems). Amplificons were analyzed by separating 12 µl of the PCR reaction on 2.0% (wt/vol) agarose (Sigma type V) gels at 3.2 V.cm¹ in TBE buffer (40 mM Tris-acetate, 1 mM EDTA [pH 8.0]), followed by ethidium bromide staining and examination under UV light. Negative controls (without DNA) were included in all amplifications.

Sequence analysis. Amplicons were purified using Wizard PCR Preps DNA Purification System (Promega) and subjected to direct bidirectional sequencing with the original primers (p515f and p806r) a Big Dye Terminator kit. Putative identifications of the 16S rDNA fragments (~240 nucleotides, excluding the primer sequences) were made by using the BLAST search algorithm. The entry having the highest homology to the submitted sequence was chosen as a reference identity for individual bands.

Results

Based on the sequence similarity to the existing GenBank database entries and traditional methods, bacterial identification revealed a complex flora with up to 13 genera (Murray et al. 2003) (Table 1). From the three L. longipalpis populations studied 19 bacteria species could be isolated and characterized (Table 1). Stenotrophomonas maltophilia was the only species common to all populations of L. longipalpis analyzed, while Enterobacter gergoviae, Enterobacter cloacae and E. coli were isolated from specimens collected in Jacobina and Lapinha Cave. Pantoea agglomerans was the only species isolated from São Luís and Lapinha Cave populations, as Acinetobacter baumannii in L. longipalpis from Jacobina and São Luís.

Thumbnail

The most diverse bacterial flora was observed in the population from Jacobina, with 12 isolated species, with the predominance of E. cloacae (32%), followed by Serratia marcescens (25%). In the population from São Luís, considering the five identified bacterial species, P. agglomerans was predominant (40%), followed by Weeksella virosa (26%) and Flavimonas oryzihabitans (16%). Nine bacterial species were identified in L. longipalpis females from Lapinha Cave, with the predominance of S. maltophilia (37%) followed by E. cloacae (25%) (Table 1).

Discussion

Many insects harbor microorganisms in symbiotic association that are essential for fecundity and viability to the host and can play a role on the establishment of parasites in the gut (Pumpuni et al. 1993). Others are stable residents or transients and are lost during digestion or insect moulting (Endris et al. 1982, Gonzalez-Ceron et al. 2003). The origin and ecological association of the midgut bacteria and the insect host is difficult to define. In this study we identified the microbiota of different Brazilian populations of L. longipalpis. However a more in depth research on the interactions between insects and their midgut bacteria is required.

S. marcescens, P. aeruginosa and P. agglomerans, commonly associated with the midgut of the analyzed sand flies, were the most frequent bacteria in three mosquitoes, Aedes triseriatus (Say), Culex pipiens (L.) and Psorophora columbiae (Dyar & Knab) (De Maio et al. 1996). K. ozaenae, also common to these mosquitoes, was not found associated to the three sand fly populations analyzed in here, but was found associated in previous screenings of L. longipalpis from Lapinha Cave by Oliveira et al. (2000). S. marcescens was also isolated in lab-colonies of Phlebotomus duboscqi (Volf et al. 2002). The ubiquitous P. agglomerans is considered the Gram negative bacterium more regularly associate to ground and plants (DeMaio et al. 1996). Interestingly, this bacterium is responsible for the production of a toxic phenol in Schistocerca gregaria (Forskal) that acts on other species of bacteria and fungi, being part of a defense mechanism to the host (Dillon & Charnley 1995). Serratia and Klebsiella were pointed out as pathogens of mosquitoes (Jadin 967, Seitz et al. 1987, Pumpuni et al. 1993, Gonzalez-Ceron et al. 2003).

Reports on gut microbiota of wild sand flies belonging to Phlebotomus showed the presence of S. marcescens, A. baumannii and P. aeruginosa (Dillon et al. 1996, Warburg 1991), which were also associated with L. longipalpis.

Bacteria from environmental sources (water, ground and debris), such as Acinetobacter, Serratia, Pseudomonas, Stenotrophomonas, Flavimonas and Enterobacter, found to be associated with L. longipalpis, were also reported to be associated with the gut of several other insects (Oliveira et al. 1998, Campbell et al. 2004, La Scola & Raoult 2004, Zayed & Bream 2004), suggesting to be part of their natural or transient flora.

Studies demonstrated that E. cloacae is the most common bacteria found in the gut of insects of medical importance or not, including sand flies (Rossiter et al. 1983, Tanada & Kaya 1993, Dillon et al. 1996). In the midgut of mosquitoes collected from the field or maintained in insectary, Enterobacter has no influence in the insect's survival. However, other bacteria can be pathogenic and lead to a high adult mortality, such as some species of Serratia and Klebsiella (Jadin 1967; Seitz et al. 1987; Pumpuni et al. 1993, 1996).

The wide geographic distribution and occurrence of S. maltophilia in the environment, including vegetal material, could explain its occurrence in all populations of L. longipalpis analyzed.

Among the nine identified bacterial species from L. longipalpis collected from Lapinha Cave, only E. cloacae and S. maltophilia were previously reported by Oliveira et al. (2000), suggesting both as residents of this sand fly population. They probably do not influence the establishment of the parasites in the gut as they were isolated from areas with leishmaniasis transmission.

The other bacteria species could be part of the transitory flora, which differ according to the food source exploited. Dillon et al. (1996) suggested that the fluctuation of the bacterial species in the gut of P. papatasi increased after blood feeding. Ingestion of the Gram negative bacteria E. coli H243 and S. marcescens by blood feeding blocked the development of the Plasmodium falciparum oocysts (Pumpuni et al. 1993, 1996) in Anopheles stephensi (Liston). The presence of high concentration of S. marcescens (Azambuja et al. 2004) and Pseudomons fluorescens (Mercado & Colon-Whitt 1982) in in vitro experiments induced Trypanosoma cruzi lysis. It can be suggested that the parasitic development in the insect vector is controlled by the presence and abundance of these microorganisms.

Representatives of the Gram negative bacteria isolated in the present study, S. marcescens, P. aeruginosa, Klebsiella spp. and Enterobacter spp., were able to produce several microbial factors, including prodigiosina (Azambuja et al. 2005). S. marcescens and P. aeruginosa synthesize others antiparasitic molecules, such as cytotoxic metalloproteases, haemolysins, antibiotics and haemagglutinins (Azambuja et al. 2005).

It is proven that Enterobacter amnigenus has the ability to re-colonize and persist in the gut of mosquitoes (Luxananil et al. 1994), being used as a host to express the Bacillus sp. toxic genes in Aedes aegypti (L.), Culex quinquefasciatus (Say) and Anopheles dirus (Peyton & Harrison) to control their larval development (Khampang et al. 1999, Tanapongpipat et al. 2003).

Promastigotes of leishmania in culture grow with difficulty when competing with bacteria. In the same way, the bacteria interfere with the development of promastigotes in the digestive tract of sand flies competing for nutrients and reducing the pH (Dillon et al. 1996). In nature, despite the probable well-balanced associations between some bacteria and sand flies, there should be natural selective pressure involving some species of bacteria, leishmania and their vectors, acting directly over the prevalence of infection by Leishmania spp.

Acknowledgments

To Dr. Ítalo Sherlock (Centro de Pesquisas Gonçalo Muniz/FIOCRUZ, Bahia), Dr. Reginaldo P. Brazil (Instituto Oswaldo Cruz/FIOCRUZ, Rio de Janeiro) and to Dr. José Maria M. Rebelo (Universidade do Maranhão) for the support during the field work. To Johannes Sebastian Paul Doehl, University of Aberdeen, for linguistic improvement of the manuscript.

Received 28/VIII/07. Accepted 18/IX/08.

Adler, S. & O. Theodor. 1927. The transmission of Leishmania tropica from artificially infected sandflies to man. Ann. Trop. Med. Parasitol. 21: 88-110.
Alves, S.B. 1986. Controle microbiano de insetos. Manole Ed., São Paulo, 407p.
Azambuja, P., D. Feder & E.S. Garcia. 2004. Isolation of Serratia marcescens in the midgut of Rhodnius prolixus: impact on the establishment of the parasite Trypanosoma cruzi in the vector. Exp. Parasitol. 107: 89-96.
Azambuja P., E.S. Garcia & N. Ratcliffe. 2005. Gut microbiota and parasite transmission by insect vectors. Trends Parasitol. 21: 568-572.
Brooks, M.A. 1964. Symbiotes and the nutrition of medically important insects. Bull. W.H.O. 31: 555-559.
Cameron, M.M., F.A. Pessoa, A.W. Vasconcelos & R.D. Ward. 1995. Sugar meal sources for the phlebotomine sandflies Lutzomyia longipalpis in Ceara State, Brazil. Med. Vet. Entomol. 9: 263-272.
Demaio, J., C.B. Pumpuni, M. Kent & J.C. Beier. 1996. The migut bacterial flora of wild Aedes triseriatus, Culex pipens e Psorophora columbiae mosquitoes. Am. J. Trop. Med. Hyg. 54: 219-223.
Dillon R.J. & A.K. Charnley. 1995. Chemical barriers to gut infection in the desert locust In vivo production of antimicrobial phenols associated with the bacteria Pantoea agglomerans J. Invertebr. Pathol. 66: 72-75.
Dillon, R.J., E. El Kordy & R.P. Lanee. 1996. The prevalence of a microbiota in the digestive tract of Phlebotomus papatasi. Ann. Trop. Med. Parasitol. 90: 669-673.
Endris, R.G., P.V. Perkins, D.G. Young & R.N. Johnson. 1982. Techniques for laboratory rearing of sandflies (Diptera: Psychodidae). Mosq. News 42: 400-407.
Gonzalez-Ceron, L., F. Santillan, M.H. Rodríguez, D. Mendez & J.E. Hernández-Avila. 2003. Bacteria in midguts of field-collected Anopheles albimanus block Plasmodium vivax sporogonic development. J. Med. Entomol. 40: 371-4.
Holt, J.G., N.R. Krieg, P.H.A. Seath, J.T. Staley & S.T. Williams. 1994. Bergey's manual of determinative bacteriology, 9th ed. Williams & Wilkins Ed., Baltimore, 804p.
Jadim, J. 1967. Du role des bacteries dans le tube digestif des insects vecteurs des Plasmodidae et des Trypanosomidae. Ann. Soc. Belg. Med. Trop. 47: 331-342.
Khampang, P., W. Chungjatupornchai, P. Luxananil & S. Panyim. 1999. Efficient expression of mosquito-larvicidal proteins in a gram-negative bacterium capable of recolonization in the guts of Anopheles dirus larva. Appl. Microbiol. Biotechnol. 51: 79- 84.
Killick-Kendrick, R. 1979. Biology of Leishmania in phlebotomine sandflies, p.395-460. In W. H. R. Lumsden & D. A., Evans (eds.), Biology of Kinetoplastida II . Academic Press, London, 738p.
Killick-Kendrick, R. & M. Killick-Kendrick. 1987. Honeydew of aphids as a source of sugar for Phlebotomus ariasi. Med. Vet. Entomol. 1: 297-302.
La Scola, B. & D. Raoult. 2004. Acinetobacter baumannii in human body louse. Emerg. Infect. Dis. 10: 1671-1673.
Luxananil, P., W. Chungjatupornchai, K. Lerdthusnee & S. Panyim. 1994. Re-colonization of bacteria isolated from the gut of field collected mosquito larvae in Aedes aegypti Proc. Calif. Mosq. Vector Control Assoc. 62: 58-60.
Mercado, T. I. & A. Colón-Whitt. 1982. Lysis of Trypanosoma cruzi by Pseudomonas fluorescens Antimicrob. Agents Chemother. 22: 1051-1057.
Murray, P.R., E.J. Baron, J.H. Jorgensen, M.A. Pfaller & R.H. Yolken. 2003. Manual of clinical microbiology. 8th ed., ASM Press, Washington DC, 2113p.
Oliveira, S.M.P. de, B.A. Moraes, C.A. Gonçalves, C.M. Giordano-Dias, J.M. D'almeida, M.D. Asensi, R.P. Mello & R.P. Brazil. 1998. Prevalência da microbiota no trato digestivo de fêmeas de Lutzomyia longipalpis (Lutz & Neiva, 1912) (Diptera: Psychodidae) provenientes do campo. Rev. Soc. Bras. Med. Trop. 33: 319-322.
Oliveira, S.M.P. de, B.A. Moraes, C.A. Gonçalves, C.M. Giordano-Dias, J.M. D'almeida, M.D. Asensi, R.P. Mello & R.P. Brazil. 2000. Prevalence of microbiota in the digestive tract of wild females of Lutzomyia longipalpis Lutz & Neiva, 1912) (Diptera: Psychodidae). Rev. Soc. Bras. Med. Trop. 33: 319-322.
Pumpuni, C.B., J. Demaio, M. Kent, J.R. Davis & J.C. Beier. 1996. Bacterial population dynamics in three Anopheline species: The impact of Plasmodium sporogonic development. Am. J. Trop. Med. Hyg. 54: 214-218.
Pumpuni, C.B., M.S. Beier, J.P. Nataro, L.D. Guers & J.R. Davis. 1993. Plasmodium falciparum: Inhibition of sporogonic development in Anopheles stephensi by gram- negative bacteria. Exp. Parasitol. 77: 195-199.
Rossiter, M.C., D.J. Howard & G.L. Buch. 1983. Symbiotic bacteria of Rhagoletis pomonella p.77-83. In R. Cavalloro (ed.), Fruit flies of economic importance A. A. Balkema, Rotterdam, 224p.
Samie, M., K.R. Wallbanks, J.S. Moore & D.H. Molineux. 1990. Glycosidase activity in the sandfly Phlebotomus papatasi Comp. Biochem. Physiol. 96B: 577-579.
Schlein, Y. 1986. Sandfly diet and Leishmania. Parasitol. Today 2: 175-177.
Schlein, Y. & A. Warburg.1986. Phytophagy and the feeding cycle of Phlebotomus papatasi (Diptera: Psychodidae) under experimental conditions. J. Med. Entomol. 23: 11-15.
Schlein, Y. & B. Yuval. 1987. Leishmaniasis in the Jordan Valley. IV. Attraction of Phlebotomus papatasi (Diptera: Psychodidae) to plants in the field. J. Med. Entomol. 50: 20-27.
Schlein, Y., I. Polacheck & B. Yuval. 1985. Mycoses, bacterial infection an antibacterial activity in sandflies (Psychodidae) and their possible role in the transmission of leishmaniasis. Parasitology 90: 57-66.
Seitz, H.M., W.A. Maier, M. Rottok & H. Becker-Feldmann. 1987. Concomitant infections of Anopheles stephensi with Plasmodium berghei and Serratia marcescens: Additive detrimental effects. Zentralbl. Bakteriol. Hyg. 266: 155-166.
Sudia, W.D. & R.W. Chaberlain. 1962. Battery operated light trap, an improved model. Mosq. News 22: 126-129.
Tanada, Y. & H.K. Kaya. 1993. Associations between insects and nonpathogenics microorganisms. In Y. Tanada & H.K. Kaya (eds.), Insect pathology, p.12-51. Academic Press, New York, 666p.
Tanapongpipat, S., N. Nantapong, J. Cole & S. Panyim. 2003. Stable integration and expression of mosquito-larvicidal genes from Bacillus thuringiensis subsp. israelensis and Bacillus sphaericus into the chromosome of Enterobacter amnigenus: A potential breakthrough in mosquito biocontrol. FEMS Microbiol. Letters 221: 243-248.
Volf, P., A. Kiewegová & A. Nemec. 2002. Bacterial colonisation in the gut of Phlebotomus duboscqi (Diptera: Psychodidae): Transtadial and the role of female diet. Folia Parasitol. 49: 73-77.
Warburg, A. 1991. Entomopathogens of phlebotomine sandflies: Laboratory experiments and natural infections. J. Invertebr. Pathol. 58: 189-202.
Zayed, M.E. & A.S. Bream. 2004. Biodiversity of the microbial flora associated with two strains of Culex pipiens (Diptera: Culicidae). Commun. Agric. Appl. Biol. Sci. 69: 229-234.

Publication Dates

Publication in this collection
27 Nov 2008
Date of issue
Oct 2008

History

Received
28 Aug 2007
Accepted
18 Sept 2008

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] Adler, S. & O. Theodor. 1927. The transmission of Leishmania tropica from artificially infected sandflies to man. Ann. Trop. Med. Parasitol. 21: 88-110.

[2] Alves, S.B. 1986. Controle microbiano de insetos. Manole Ed., São Paulo, 407p.

[3] Azambuja, P., D. Feder & E.S. Garcia. 2004. Isolation of Serratia marcescens in the midgut of Rhodnius prolixus: impact on the establishment of the parasite Trypanosoma cruzi in the vector. Exp. Parasitol. 107: 89-96.

[4] Azambuja P., E.S. Garcia & N. Ratcliffe. 2005. Gut microbiota and parasite transmission by insect vectors. Trends Parasitol. 21: 568-572.

[5] Brooks, M.A. 1964. Symbiotes and the nutrition of medically important insects. Bull. W.H.O. 31: 555-559.

[6] Cameron, M.M., F.A. Pessoa, A.W. Vasconcelos & R.D. Ward. 1995. Sugar meal sources for the phlebotomine sandflies Lutzomyia longipalpis in Ceara State, Brazil. Med. Vet. Entomol. 9: 263-272.

[7] Demaio, J., C.B. Pumpuni, M. Kent & J.C. Beier. 1996. The migut bacterial flora of wild Aedes triseriatus, Culex pipens e Psorophora columbiae mosquitoes. Am. J. Trop. Med. Hyg. 54: 219-223.

[8] Dillon R.J. & A.K. Charnley. 1995. Chemical barriers to gut infection in the desert locust In vivo production of antimicrobial phenols associated with the bacteria Pantoea agglomerans J. Invertebr. Pathol. 66: 72-75.

[9] Dillon, R.J., E. El Kordy & R.P. Lanee. 1996. The prevalence of a microbiota in the digestive tract of Phlebotomus papatasi. Ann. Trop. Med. Parasitol. 90: 669-673.

[10] Endris, R.G., P.V. Perkins, D.G. Young & R.N. Johnson. 1982. Techniques for laboratory rearing of sandflies (Diptera: Psychodidae). Mosq. News 42: 400-407.

[11] Gonzalez-Ceron, L., F. Santillan, M.H. Rodríguez, D. Mendez & J.E. Hernández-Avila. 2003. Bacteria in midguts of field-collected Anopheles albimanus block Plasmodium vivax sporogonic development. J. Med. Entomol. 40: 371-4.

[12] Holt, J.G., N.R. Krieg, P.H.A. Seath, J.T. Staley & S.T. Williams. 1994. Bergey's manual of determinative bacteriology, 9th ed. Williams & Wilkins Ed., Baltimore, 804p.

[13] Jadim, J. 1967. Du role des bacteries dans le tube digestif des insects vecteurs des Plasmodidae et des Trypanosomidae. Ann. Soc. Belg. Med. Trop. 47: 331-342.

[14] Khampang, P., W. Chungjatupornchai, P. Luxananil & S. Panyim. 1999. Efficient expression of mosquito-larvicidal proteins in a gram-negative bacterium capable of recolonization in the guts of Anopheles dirus larva. Appl. Microbiol. Biotechnol. 51: 79- 84.

[15] Killick-Kendrick, R. 1979. Biology of Leishmania in phlebotomine sandflies, p.395-460. In W. H. R. Lumsden & D. A., Evans (eds.), Biology of Kinetoplastida II . Academic Press, London, 738p.

[16] Killick-Kendrick, R. & M. Killick-Kendrick. 1987. Honeydew of aphids as a source of sugar for Phlebotomus ariasi. Med. Vet. Entomol. 1: 297-302.

[17] La Scola, B. & D. Raoult. 2004. Acinetobacter baumannii in human body louse. Emerg. Infect. Dis. 10: 1671-1673.

[18] Luxananil, P., W. Chungjatupornchai, K. Lerdthusnee & S. Panyim. 1994. Re-colonization of bacteria isolated from the gut of field collected mosquito larvae in Aedes aegypti Proc. Calif. Mosq. Vector Control Assoc. 62: 58-60.

[19] Mercado, T. I. & A. Colón-Whitt. 1982. Lysis of Trypanosoma cruzi by Pseudomonas fluorescens Antimicrob. Agents Chemother. 22: 1051-1057.

[20] Murray, P.R., E.J. Baron, J.H. Jorgensen, M.A. Pfaller & R.H. Yolken. 2003. Manual of clinical microbiology. 8th ed., ASM Press, Washington DC, 2113p.

[21] Oliveira, S.M.P. de, B.A. Moraes, C.A. Gonçalves, C.M. Giordano-Dias, J.M. D'almeida, M.D. Asensi, R.P. Mello & R.P. Brazil. 1998. Prevalência da microbiota no trato digestivo de fêmeas de Lutzomyia longipalpis (Lutz & Neiva, 1912) (Diptera: Psychodidae) provenientes do campo. Rev. Soc. Bras. Med. Trop. 33: 319-322.

[22] Oliveira, S.M.P. de, B.A. Moraes, C.A. Gonçalves, C.M. Giordano-Dias, J.M. D'almeida, M.D. Asensi, R.P. Mello & R.P. Brazil. 2000. Prevalence of microbiota in the digestive tract of wild females of Lutzomyia longipalpis Lutz & Neiva, 1912) (Diptera: Psychodidae). Rev. Soc. Bras. Med. Trop. 33: 319-322.

[23] Pumpuni, C.B., J. Demaio, M. Kent, J.R. Davis & J.C. Beier. 1996. Bacterial population dynamics in three Anopheline species: The impact of Plasmodium sporogonic development. Am. J. Trop. Med. Hyg. 54: 214-218.

[24] Pumpuni, C.B., M.S. Beier, J.P. Nataro, L.D. Guers & J.R. Davis. 1993. Plasmodium falciparum: Inhibition of sporogonic development in Anopheles stephensi by gram- negative bacteria. Exp. Parasitol. 77: 195-199.

[25] Rossiter, M.C., D.J. Howard & G.L. Buch. 1983. Symbiotic bacteria of Rhagoletis pomonella p.77-83. In R. Cavalloro (ed.), Fruit flies of economic importance A. A. Balkema, Rotterdam, 224p.

[26] Samie, M., K.R. Wallbanks, J.S. Moore & D.H. Molineux. 1990. Glycosidase activity in the sandfly Phlebotomus papatasi Comp. Biochem. Physiol. 96B: 577-579.

[27] Schlein, Y. 1986. Sandfly diet and Leishmania. Parasitol. Today 2: 175-177.

[28] Schlein, Y. & A. Warburg.1986. Phytophagy and the feeding cycle of Phlebotomus papatasi (Diptera: Psychodidae) under experimental conditions. J. Med. Entomol. 23: 11-15.

[29] Schlein, Y. & B. Yuval. 1987. Leishmaniasis in the Jordan Valley. IV. Attraction of Phlebotomus papatasi (Diptera: Psychodidae) to plants in the field. J. Med. Entomol. 50: 20-27.

[30] Schlein, Y., I. Polacheck & B. Yuval. 1985. Mycoses, bacterial infection an antibacterial activity in sandflies (Psychodidae) and their possible role in the transmission of leishmaniasis. Parasitology 90: 57-66.

[31] Seitz, H.M., W.A. Maier, M. Rottok & H. Becker-Feldmann. 1987. Concomitant infections of Anopheles stephensi with Plasmodium berghei and Serratia marcescens: Additive detrimental effects. Zentralbl. Bakteriol. Hyg. 266: 155-166.

[32] Sudia, W.D. & R.W. Chaberlain. 1962. Battery operated light trap, an improved model. Mosq. News 22: 126-129.

[33] Tanada, Y. & H.K. Kaya. 1993. Associations between insects and nonpathogenics microorganisms. In Y. Tanada & H.K. Kaya (eds.), Insect pathology, p.12-51. Academic Press, New York, 666p.

[34] Tanapongpipat, S., N. Nantapong, J. Cole & S. Panyim. 2003. Stable integration and expression of mosquito-larvicidal genes from Bacillus thuringiensis subsp. israelensis and Bacillus sphaericus into the chromosome of Enterobacter amnigenus: A potential breakthrough in mosquito biocontrol. FEMS Microbiol. Letters 221: 243-248.

[35] Volf, P., A. Kiewegová & A. Nemec. 2002. Bacterial colonisation in the gut of Phlebotomus duboscqi (Diptera: Psychodidae): Transtadial and the role of female diet. Folia Parasitol. 49: 73-77.

[36] Warburg, A. 1991. Entomopathogens of phlebotomine sandflies: Laboratory experiments and natural infections. J. Invertebr. Pathol. 58: 189-202.

[37] Zayed, M.E. & A.S. Bream. 2004. Biodiversity of the microbial flora associated with two strains of Culex pipiens (Diptera: Culicidae). Commun. Agric. Appl. Biol. Sci. 69: 229-234.

Brasil

Brasil

Study on the bacterial midgut microbiota associated to different Brazilian populations of Lutzomyia longipalpis (Lutz & Neiva) (Diptera: Psychodidae)

Estudo sobre as bactérias da microbiota intestinal de diferentes populações brasileiras de Lutzomyia Longipalpis (Lutz & Neiva) (Diptera: Psychodidae)

Abstracts

Publication Dates

History